Tunable room-Temperature single-photon emission at telecom wavelengths from sp 3 defects in carbon nanotubes

Abstract

Generating quantum light emitters that operate at room temperature and at telecom wavelengths remains a significant materials challenge. To achieve this goal requires light sources that emit in the near-infrared wavelength region and that, ideally, are tunable to allow desired output wavelengths to be accessed in a controllable manner. Here, we show that exciton localization at covalently introduced aryl sp 3 defect sites in single-walled carbon nanotubes provides a route to room-Temperature single-photon emission with ultrahigh single-photon purity (99%) and enhanced emission stability approaching the shot-noise limit. Moreover, we demonstrate that the inherent optical tunability of single-walled carbon nanotubes, present in their structural diversity, allows us to generate room-Temperature single-photon emission spanning the entire telecom band. Single-photon emission deep into the centre of the telecom C band (1.55â €..μm) is achieved at the largest nanotube diameters we explore (0.936â €..nm).